PT88321B - WRITTEN TRANSPARENCY PROJECTOR - Google Patents

Abstract

An overhead projector having an illumination component with extremely reduced constructional height is described. The main component of the illumination component is a reflection surface which is covered either on its upper side or on its lower side with mirrored prismatic strips which run parallel with one another and reflect the light from at least one laterally arranged light source to the Fresnel lens, writing plate and projection lens. The reflection surface can be plane, but also circular-shaped, hyperbolic or curved in the longitudinal direction of the prism strips. This curving can be continuous or non-continuous. In addition, the reflection surface can also be turned in on itself, i.e. it can also be curved in the direction perpendicular to the extension of the prism strips and this curving can also be continuous or also non-continuous. However, the prism angles of the individual prism strips are always determined individually in such a way that the light appears to come from a light source arranged apparently centrally below the Fresnel lens. <IMAGE>

Description

Description referring to the ProCent Patentund Verwaltungs AG, Swiss, industrial and commercial patent, based in Dufour Str. 117, CH-3O29 Zlirich, Switzerland (inventor: D i p 1. - |

-Ing. Karl-Gbnther Behr, residing in West Germany),!

for WRITTEN TRANSPARENCY PROJECTOR.

description

The present invention relates to the lighting part of a projector of written transparencies.

In projectors of written transparencies, as is known, the light source is placed below the written transparency. In general, the path of the light rays from the light source takes place through a Fresnel lens, placed under the written transparency, which focuses the rays through the written transparency. is moving to the projection lens.

In order to achieve a uniform illumination of the written transparency, it is necessary that the light source is located relatively below the Fr es lel lens, so that the angle of incidence on this lens is not too large. This requires a minimum construction height that makes a written transparency projector a very bulky instrument. Therefore, numerous studies and proposals have already been made to try to reduce this construction height and obtain projectors that need less space.

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These proposals consist of placing the light source laterally just below the Fresnel lens and reflecting the light beam through a deviation mirror placed under the Fresnel lens onto the plate where the transparency is placed.

The invention falls outside this prior art. It aims to provide a projector for written transparencies whose height is even lower than what happens in projectors hitherto known with side light source and deviation mirror.

This objective is achieved by a projector of transparencies written with a lighting set that has the characteristics mentioned in Claim 1.

The way to achieve that goal is to make a large number of small streaks in the large deviation mirror placed under the Fresnel lens and place them on a flat reflection surface. This is achieved technically in the best way by shaping these ridges of prismatic strip surfaces that are placed parallel to each other on a surface, the reflection surface. In this way, the space needed for the deviation mirror is saved so that the height of construction of the lighting set of such a projector of written transparencies can be essentially reduced and at a distance from the Fresnel lens that is necessary to allow to focus sufficient light from the light source on the reflection surface.

But this distance can also be reduced if, in particular, not only one but two light sources are used and these light sources are placed laterally symmetrically in relation to the reflection surface. These two light sources can then naturally be smaller than if one used

only one and nevertheless provide a beam of light with the same intensity. These prismatic strips must then be placed with their angle of the prism symmetrically in relation to the light sources from the median plane defined by the optical axis of the device.

Prismatic strips can be placed not only on the top side but also on the bottom side of the reflection surface. In the latter case, it is advisable to mirror the top side, in order to reflect the maximum possible amount of light rays entering the surface or the reflection disc, in which they are reflected backwards by the prismatic rulers that are underneath mirrored externally. te.

In order to avoid all shadows in the incidence of light rays on the prismatic strips, it is also foreseen that the reflection surface does not consist of a flat surface but that it is curved in the longitudinal direction of the prismatic strips. This curving can, in concrete practice, take several forms. The reflection surface can be curved towards one or the other side. In one case (concave in relation to the plate with the written transparency), it is shaped like part of a hollow cylinder on whose underside the prismatic rulers develop; in the other case (convex in relation to the writing plate for the written transparencies), it represents the wall of an almost complete cylinder, on the outside of which are placed the prismatic rulers.

The curvature of the reflection surface should not always be constant (so the surface would then be in cross-section a part of the arc of the circle) but, on the contrary, it can also be non-constant, for example, only be more strongly curved at the ends than in the middle zone.

Finally, the reflection surface can additionally be further twisted.

This embodiment is of particular interest if only one light source is placed laterally under the plate with the written transparency.

By twisting it is understood that the reflection surface is curved not only in the direction of the prismatic strips, but also that it also has a curvature in the direction perpendicular to the direction of the prismatic strips. The exact type of curvature can be deduced from one of the special embodiments described below.

The prismatic strips always extend in the direction of a curvature and the light source, preferably the two light sources; placed symmetrically, they are on the front side of the hollow cylinder or the convex cylinder.

Between the type and the value of the curvature, on the one hand, and the angles of the prisms in the different prismatic rulers, on the other hand, there is a tight relationship. The angles of the prisms of all the strips must be individually determined, having a value such that the light rays in their entirety constitute an imaginary virtual light source that is very far below the Fresnel lens or the plate with the written transparency.

In the drawing, the invention is shown in the form of two embodiments. In them, Figure 1 schematically represents the reflection surface of a projector of transparencies written with the prismatic rulers placed on the surface;

Figure 2 schematically represents the reflection surface of a written transparency projector, with the prismatic rulers placed on its surface4

lower species;

Figure 3 schematically represents a lighting set for a screened overhead projector, with the curved reflection surface;

Figure 4 represents a view of Figure 3 rotated by 90 °; and Figure 5 schematically represents the lighting set of a transparency projector

Ί; written, with a reflection surface itself known.

In Figure I the principle of the reflection surface is schematically represented, in a very simple way, according to the present invention. Desi! the light source is set to 1, whose rays fall on the reflection surface 2. Then, they are reflected to a Fresnel lens 3, and, after passing through the plate of written transparency 4, reach the projection objective, not shown .

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i The reflection surface 2 is provided with prismatic rulers 5 on its surface, which are perpendicular to the drawing plane, so that the prisms are represented in the Figure in cross section. The surfaces of the prisms facing the light source 1 are spread out and the angles of the prisms are determined individually in each prismatic ruler, so that the scattered surfaces of the prisms reflect the light rays that fall on the Fresnel 3 lens, in the same way indicated.

With 1, the light source is also designated. 12 is the twisted reflection surface, over which the Fresnel lens 3 and the writing transparency plate 4 are located. In the light sources 1, there are two parts of which, in Figure 3, only the rear part is visible. In Figure 3, the curvature of the

reflection surface 12. It should be noted that, in this view, the view over the mirrored prismatic surface of a prismatic ruler is missing. You can also see the curvature of the reflection surface evolving in the longitudinal direction of the prismatic rulers.

Figure 4 represents a 90 degree rotated view. In it, the two light sources are seen and the curving of the reflection surface 12 takes place increasingly backwards, along this surface.

In Figure 5, a reflection surface 2, represented by itself, is shown. This reflection surface is curved both in the direction of the prismatic strips 5 (= x direction), as well as in the perpendicular direction (= y direction). In this case, the curvature in the y direction is not continuous but is discontinued and changes from concave (= part of the right of the surface) passing through null (= medium prismatic rule) to convex (= left part of the surface).

Finally, it should be pointed out that the mentioned types of curving of the reflection surface are simply possible examples for real curving. The course of the curving curves (circular, hyperbolic, convex or concave shape and additionally possibly even in a twisted way = Figure 5) can be freely chosen. Regarding the relationship between the curvature progress and the angles of the prisms, reference has already been made. The angles of the prisms must always be chosen so that the visible rays of light from the light source 6, placed centrally under the Fresnel lens are always visible.

From Figure 1, the principle of the reflection surface according to the present invention can also be recognized, which consists in the fact that the large deviation mirror existing in the devices according to the current state of the art be placed

individual strips, prismatic strips, so that the building height A can be reduced to a minimum.

It is clarified that if two light sources 1 are used, namely one on each side, the prismatic strips that come out of the middle part with their reflective prismatic surfaces are placed symmetrically in relation to the respective light sources and that the angles of the prisms are chosen from the outside in an equally symmetrical way (or vice versa).

In Figure 2, an embodiment is shown and, in fact, an example of a reflection surface 14, in which the prismatic rulers 5 are placed at the bottom of the reflection surface. In this case, the light rays enter from the underside through the non-mirrored reflection surface and meet on the underside on the prismatic strips. 5 mirrored externally with its angle of the prism ° (in each rule determined individually, so that the rays that reflect there can all come from the light source 6, placed under the Fresnel lens 3.

In Figures 3 and 4, an example of an embodiment with a twisted reflection surface 12 is shown, in which the prismatic rulers 5 are placed on the top side of the reflection surface corresponding to the example shown in Figure 1. As already mentioned, the curving of the reflection surface serves to avoid shadows in the path of the light rays to the Fresnel lens that are sent to the environment in the case of a flat reflection surface, without being used.

Claims (1)

Projector of written transparencies comprising a Fresnel lens (3) with a writing support (4), a reflective surface (2; 12; 14) mounted: fixedly under the Fresnel lens and a lighting set with a light source (1) mounted laterally between the reflecting surface and the Fresnel lens, where the reflecting surface is provided with reflective coated prismatic strips (5) that extend parallel to each other and whose angles of (ç <) are different for each prismatic and individually determined ruler, characterized by the fact that the angles of the prisms (oO are determined in such a way that the rays of the light source (1) that are reflected into the Fresnel lens apparently come from an imaginary light source ( 6) placed on the optical axis of the projector and below the reflecting surface because the reflecting surface is curved in the longitudinal direction of the prismatic strips (5) and by the angle of the prism; (ca.) of each prismatic ruler (5) be i n d i v i d ua 1 m and t adapted to this curvature. - ^a Projector according to claim ί 1, characterized in that said curvature is concave [in relation to the Fresnel lens (3). - ^the third projector according to claim 1, characterized in that the said curvature is convex in relation to the fresnel lens (3). - / ½ - | ί Projector according to one of claims 2 or 3, characterized in that the curvature of the reflecting surface is constant. j - 5 ^to -; t I I Projector according to one of claims 2 or 3, characterized in that the curvature of the reflecting surface is variable. Projector according to one of claims 2 to 5, characterized in that the reflective surface, in addition to being curved in relation to the direction of the prismatic strips, is also curved in relation to the perpendicular direction. - 7 ^to 6, characterized by; constant curvature. Projector according to the claim that the additional curvature is a variable curvature - 8 ^a Projector according to the claim; 6, characterized in that the additional curvature is one that extends from a concave curvature, passes through zero and extends to a convex curvature. The applicant declares that the first! This patent application was filed in the German Federal Republic on August 24, 1987, under N ^and P 37 28 191.7.